Quantum dynamics of skyrmions in chiral magnets

Christina Psaroudaki, Silas Hoffman, Jelena Klinovaja, Daniel Loss

Published 2016-12-06Version 1

We study the quantum propagation of a skyrmion in chiral magnetic insulators by generalizing the micromagnetic equations of motion to a finite temperature path integral formalism, using field theoretic tools. Promoting the center of the skyrmion to a dynamic quantity, the fluctuations around the skyrmionic configuration give rise to a time-dependent damping of the skyrmion motion. From the frequency dependence of the damping kernel, we are able to identify the skyrmion mass, thus providing a microscopic description of the kinematic properties of skyrmions. When the free energy is translationally invariant we find the skyrmion mass is finite only at finite temperature. However, if defects are present or a magnetic trap is applied, the skyrmion mass acquires a finite value, even at vanishingly small temperature. We demonstrate that a skyrmion in a confined geometry provided by a magnetic trap behaves as a massive particle owing to its quasi-one dimensional confinement.